Evidence for presence of GABA-ergic receptor mediated dispersion in isolated scale melanophores of a carp,Cirrhinus mrigala Ham

Effects of GABA-ergic agonists and antagonists were examined on the melanophores of a carp C. mrigala in vitro. GABA and baclofen both induced concentration - related dispersion in fish melanophores. Denervation of the melanophores by reserpine treatment potentiated the sensitivity of the melanophores to GABA. While denervation by cooling treatment inhibited the sensitivity of the melanophores to GABA, atropine, bicuculline and pentylenetetrazole all inhibited the dispersal responses of the melanophores induced by higher concentrations of GABA. 5-aminovaleric acid also significantly inhibited the dispersion of the melanophores induced either by GABA or baclofen. It is concluded that GABA-ergic agonist induced dispersal responses in C mrigala melanophores are mediated through specific GABA receptors. The presence of both GABAA and GABAB receptors in this fish melanophores has been indicated.     

beta-Adrenergic receptor subtypes in melanophores of the marine gobies Tridentiger trigonocephalus and Chasmichthys gulosus.

The subtype of beta-adrenergic receptors in melanophores of the marine gobies Tridentiger trigonocephalus and Chasmichthys gulosus was studied. Pigment of denervated melanophores in isolated, split caudal fins was preliminarily aggregated by incubating the specimens in a physiological saline containing 10 microM phentolamine and 30-100 microM verapamil or 2-10 nM melatonin, and the responses of the melanophores to a beta-adrenergic agonist added to the incubating medium were recorded photoelectrically. The beta-adrenergic agonists noradrenaline, adrenaline, isoproterenol, salbutamol and, dobutamine were all effective in evoking a dispersion of melanophore pigment in the presence of phentolamine and verapamil or melatonin. The pigment-dispersing effect of noradrenaline (beta 1-selective agonist) was inhibited by metoprolol (beta 1-selective antagonist), propranolol,- and butoxamine. Whereas, the effect of salbutamol (beta 2-selective agonist) was hardly inhibited by metoprolol, though it was considerably inhibited by propranolol and ICI-118551. It was estimated that beta 1- and beta 2-adrenergic receptors coexist at ratios of 8.6:91.4, in the melanophore of Tridentiger trigonocephalus, and 25:75, in the melanophore of Chasmichthys gulosus, through the analyses of Hofstee plots of the effects of the beta-adrenergic drugs. It was suggested that the relation between the pigment-dispersing effect of a beta-adrenergic agonist on the melanophores and the concentration of the drug follows mass action kinetics, when the effect is mainly caused by the activation of beta 2-adrenergic receptors of the melanophores. However, when it is mainly caused by the activation of beta 1-adrenergic receptors of the melanophores, the relation does not follow mass action kinetics.     

β-Adrenergic Receptor Subtypes in Melanophores of the Marine Gobies Tridentiger trigonocephalus and Chasmichthys gulosus

The subtype of β-adrenergic receptors in melanophores of the marine gobies Tridentiger trigonocephalus and Chasmichthys gulosus was studied. Pigment of denervated melanophores in isolated, split caudal fins was preliminarily aggregated by incubating the specimens in a physiological saline containing 10 μM phentolamine and 30–100 μM verapamil or 2–10 nM melatonin, and the responses of the melanophores to a β-adrenergic agonist added to the incubating medium were recorded photoelectrically. The β-adrenergic agonists noradrenaline, adrenaline, isoproterenol, salbutamol and, dobutamine were all effective in evoking a dispersion of melanophore pigment in the presence of phentolamine and verapamil or melatonin. The pigment-dispersing effect of noradrenaline (β₁-selective agonist) was inhibited by metoprolol (β₁-selective antagonist), propranolol, and butoxamine. Whereas, the effect of salbutamol (β₂-selective agonist) was hardly inhibited by metoprolol, though it was considerably inhibited by propranolol and ICI-118551. It was estimated that β₁- and β₂-adrenergic receptors coexist at ratios of 8.6:91.4, in the melanophore of Tridentiger trigonocephalus, and 25:75, in the melanophore of Chasmichthys gulosus, through the analyses of Hofstee plots of the effects of the β-adrenergic drugs. It was suggested that the relation between the pigment-dispersing effect of a β-adrenergic agonist on the melanophores and the concentration of the drug follows mass action kinetics, when the effect is mainly caused by the activation of β₂-adrenergic receptors of the melanophores. However, when it is mainly caused by the activation of β₁-adrenergic receptors of the melanophores, the relation does not follow mass action kinetics.     

Basic properties of beta adrenergic receptors mediating melanosome dispersion of melanophores in a cyprinid fish, Zacco temmincki

In melanophores of a cyprinid fish, Zacco temmincki, receptor mechanisms of melanosome dispersion induced by catecholamines were examined. While possessing a melanosome-aggregating action in higher concentrations, isoproterenol and epinephrine in lower concentrations acted to disperse melanosomes. Norepinephrine, epinine and dopamine altered their action from melanosome aggregation to melanosome dispersion after alpha adrenergic blockade. The catecholamine-induced melanosome dispersion was inhibited by beta adrenergic blocking agents. Mediation of dispersion is regulated through beta adrenergic receptors. The beta adrenergic responses were unaffected by mersalyl, a sulfhydryl inhibitor. A prospective substance acting in dispersing melanosomes appears to be adrenaline, but not noradrenaline.     

Cellular Aspects of the Control of Physiological Color Changes in Amphibians

SYNOPSIS. The present paper is concerned mainly with the melanin-dispersingeffect of melanocyte-stimulating hormones (MSH's) on the skinmelanophores of amphibians. In addition, some of the more recentevidence for the unihumoral theory of the control of color changeis reviewed. The mechanism of dispersion of melanin is stillunknown, but evidence is accumulating that the action of MSHmay be mediated by an increase in the melanophoric content ofadenosine 3', 5'-monophosphate (cyclic AMP). For example, cyclicAMP has a specific, reversible melanin-dispersing effect onthe melanophores of the isolated skin of R. pipiens and Xenopuslaevis. It also has a reversible "melanophore—expanding"effect on the tissue—cultured embryonic melanophores ofthe spotted salamander, Ambystoma maculatum. The effect of cyclicAMP on melanophores of R. pipiens does not require sodium butis inhibited by hypertonicity. Finally, new evidence is presented that confirms that the melanin-dispersingeffect of catecholamines on melanophores of X. laevis is mediatedby beta adrenergic receptors,because it is blocked by the highlyspecific ß—blocking agent, propranolol. On theother hand, the melanin-aggregating effect of catecholamineson amphibian melanophores appears to be mediated by alpha adrenergicreceptors. There is even a possibility that the effects of catecholaminesare also mediated through a control of cyclic AMP levels inmelanophores, with beta adrenergic stimulation producing anincrease in cyclic AMP levels, followed by dispersion of melanin,and alpha adrenergic stimulation producing a decrease in cyclicAMP levels, followed by aggregation of melanin.     

Photoaffinity Labelling of MSH Receptors on Anolis Melanophores: Effects of Catecholamines,Calcium and Forskolin

Abstract

Photoaffinity labelling of MSH receptors on Anolis melanophores was used as a tool for studying the effects of catecholamines, calcium and forskolin on hormone-receptor interaction and receptor-adenylate cyclase coupling. Covalent attachment of photoreactive α-MSH to its receptor was suppressed in calcium-free buffer but was hardly influenced by catecholamines or forskolin. The longlasting signal generated by the covalent MSH-receptor complex was readily and reversibly abolished by adrenaline, noradrenaline, dopamine or clonidine or by the absence of calcium. The suppression of pigment dispersion by catecholamines was blocked by the simultaneous presence of yohimbine but not prazosin, indicating that the catecholamines antagonize the α-MSH signal by inhibitory action on the adenylate cyclase system through an alpha-2 receptor. Forskolin, which stimulates melanophores by direct action on the catalytic unit of the adenylate cyclase and at about the same speed as α-MSH, produced a slower and weaker response in the presence of noradrenaline. If MSH receptors were covalently labelled and then exposed to noradrenaline, the characteristics of the forskolin-induced response were identical to those of unlabelled cells that had not been exposed to noradrenaline. This may point to a partial restoration of receptor-adenylate cyciase coupling by forskolin. The results show that the longlasting stimulation of Anolis melanophores by photoaffinity labelling proceeds via a permanently stimulated adenylate-cyclase system whose coupling to the receptor depends on calcium and is abolished by alpha-2 receptor agonists. Calcium is also essential for hormone-receptor binding.     

Receptor mechanisms in fish chromatophores--VIII. Mediated by beta adrenoceptors, catecholamines always act to disperse pigment in siluroid melanophores

The sympathomimetic amines tested, including those of alpha and beta type, were all ineffective in arousing melanosome aggregation within dermal and epidermal melanophores of the siluroid catfish, Parasilurus asotus. Conversely, these amines unfailingly gave rise to a dispersion of the pigment. While alpha-adrenergic blocking agents had only a little influence, beta agents exhibited a strong inhibitory effect on the pigment-dispersing action of the amines. Electrical nervous stimulation failed to bring about a melanosome dispersion. It was concluded that the adrenoceptors possessed by dermal and epidermal melanophores of this species seemed to be solely of the beta-adrenergic type, mediating the pigment dispersion, and that the endogenous amines involved in the darkening reaction of animals may originate in adrenal chromaffin cells, and thus are not derived from the peripheral nervous elements.     

Identification of novel hexapeptide agonists at the Xenopus laevis melanophore melanocortin receptor

We used a combinatorial chemical approach to identify novel agonists for the endogenous melanocortin receptor expressed in Xenopus laevis melanophores. A random one-bead one-compound hexapeptide library was screened to detect new molecules able to induce pigment dispersion in melanophores. Our approach led to the discovery of seven related novel peptides able to stimulate pigment dispersion with EC50 in the range of 0.1-10 microM. Their action was inhibited by the amphibian melanocortin receptor antagonist dWRL. These novel peptides share no significant sequence homology with known melanocortins. This study may aid in the understanding of the chemical interaction between the melanocortin receptors and their ligands.     

Receptor mechanisms in fish chromatophores--VI. Adenosine receptors mediate pigment dispersion in guppy and catfish melanophores

Using the guppy, Lebistes reticulatus, and the siluroid catfish, Parasilurus asotus , the effects of purine and pyrimidine derivatives on the movement of melanophores were studied. All the substances tested did not aggregate pigment within melanophores. Adenosine and adenine nucleotides were very effective in dispersing melanosomes within the cell, although adenine itself lacked such action. Derivatives of other purines than adenine and of pyrimidines did not disperse melanosomes. The pigment dispersion induced by adenine derivatives was specifically antagonized by methylxanthines. It was concluded that adenosine receptors are present on the melanophore membrane, which take part in the darkening reaction of fishes.     

Comparative analyses of the pigment-aggregating and -dispersing actions of MCH on fish chromatophores

In melanophores of the peppered catfish and the Nile tilapia, melanin-concentrating hormone (MCH) at low doses (<1 μM) induced pigment aggregation, and the aggregated state was maintained in the presence of MCH. However, at higher MCH concentrations (such as 1 and 10 μM), pigment aggregation was immediately followed by some re-dispersion, even in the continued presence of MCH, which led to an apparent decrease in aggregation. This pigment-dispersing activity at higher concentrations of MCH required extracellular Ca²⁺ ions. By contrast, medaka melanophores responded to MCH only by pigment aggregation, even at the highest concentration employed (10 μM). Since it is known that medaka melanophores possess specific receptors for α-melanophore-stimulating hormone (α-MSH), the possibility that interaction between MSH receptors and MCH at high doses in the presence of Ca²⁺ might cause pigment dispersion is ruled out. Cyclic MCH analogs, MCH (1–14) and MCH (5–17), failed to induce pigment dispersion, whereas they induced aggregation of melanin granules. These results suggest that another type of MCH receptor that mediates pigment dispersion is present in catfish and tilapia melanophores, and that intact MCH may be the only molecule that can bind to these receptors. Determinations of cAMP content in melanophores, which were isolated from the skin of three fish species and treated with 10 nM or 10 μM MCH, indicate that MCH receptors mediating aggregation may be coupled with Gi protein, whereas MCH receptors that mediate dispersion may be linked to Gs. The response of erythrophores, xanthophores and leucophores to MCH at various concentrations was also examined, and the results suggest that the distribution patterns of the two types of MCH receptors may differ among fish species and among types of chromatophore in the same fish.     

Subtypes of beta adrenergic receptors mediating pigment dispersion in chromatophores of the medaka, Oryzias latipes

Actions of the adrenergic beta-2 agonists, salbutamol and terbutaline, and the beta-1 antagonists, metoprolol and atenolol, were examined on denervated melanophores and leucophores of a teleost, Oryzias latipes. Beta-2 agonists depressed the pigment-aggregation response of melanophores to norepinephrine, while beta-1 antagonists inhibited the dispersion response of leucophores to isoproterenol but not the melanophore response. These findings suggest that adrenergic receptors mediating pigment dispersion in melanophores are beta-2 and those of leucophores are beta-1. The possible relations between receptor mechanisms and the responses of chromatophores are discussed.     

A Melanophore-Based Screening Assay for Erythropoietin Receptors

A rapid, functional assay in frog melanophore cells for the erythropoietin receptor (EPOR), a member of the cytokine receptor family, is demonstrated. A chimeric receptor that comprised the extracellular portion of the murine EPOR and the transmembrane and intracellular domains of the human epidermal growth factor receptor (EGFR) was subcloned into the expression vector pJG3.6. When the full-length EGFR was expressed in melanophores, EGF but not EPO mediated pigment dispersion in a time- and dose-dependent manner with an EC50 of 12.6 6 2.9 pM. However, when the chimeric EPOR/EGFR was expressed, EPO but not EGF stimulated pigment dispersion in a time- and dose-dependent manner with an EC50 of 380 6 107 pM. Neither EGF nor EPO had any effect on pigment dispersion in wild-type melanophores. EGF- and EPO-mediated pigment dispersion was blocked by the bis-indolylmaleimide protein kinase C inhibitor Ro 31-8220. This study extends the use of the melanophore-based bioassay to include cytokine receptors in addition to G protein- and tyrosine kinase-coupled receptors. It represents a potentially powerful method for screening of combinatorial libraries to identify novel small molecule agonists and antagonists to this clinically important class of binding sites as well as performing studies of functional ligand-receptor interactions.     

Maxadilan activates PAC1 receptors expressed in Xenopus laevis xelanophores

Functional interactions between ligands and their cognate receptors can be investigated using the ability of melanophores from Xenopus laevis to disperse or aggregate their pigment granules in response to alterations in the intracellular levels of second messengers. We have examined the response of long-term lines of cultured melanophores from X. laevis to pituitary adenylate cyclase activating peptide (PACAP), a neuropeptide with vasodilatory activity, and maxadilan, a vasodilatory peptide present in the salivary gland extracts of the blood feeding sand fly. Pituitary adenylate cyclase activating peptide increased the intracellular levels of cyclic adenosine monophosphate (cAMP) and induced pigment dispersion in the pigment cells, confirming that melanophores express an endogenous PACAP receptor. Maxadilan did not induce a response in non-transfected melanophores. When the melanophores were transfected with complementary DNA (cDNA) from the three different members of the PACAP receptor family, maxadilan induced pigment dispersion specifically and cAMP accumulation in melanophores transfected with the cDNA for PAC1 receptors but not VPAC1 or VPAC2 receptors. A melanophore line was generated that stably expresses the PAC1 receptor.     

Physiological Color Changes in Reptiles

SYNOPSIS. The physiological regulation of color changes in reptilesas studied in the lizard, Anolis carolinensis, is discussed.In Anolis, the ability to adapt to a background is dependentupon the level of circulating MSH, therelease of which is dependenton information received through the eyes. Blinded (or intact)lizards are brown under conditions of strong illumination andgreen under conditions of lower light intensities, and, again,these color changes are regulated by MSH. According to Kleinholz,color changes in the blinded lizard are regulated by dermalphotoreceptors. High or low temperatures directly affect thecolor of Anolis skins and alter the rate at which skins respondto hormones. Aggregationof melanin granules within Anolis melanophoresin response to sympathomimetic stimulation is regulated throughalpha adrenergic receptors whereas dispersion of melanin granulesin response to such stimulation is controlled through beta adrenergicreceptorspossessed by the melanophores. Most Anolis melanophores possessboth alpha and beta adrenergic receptors, but some melanophorespossess only beta adrenergic receptors. In the normal physiologyof the lizard, under conditions of stress, stimulation of alphaadrenergic receptors by catecholamines leads to an "excitement—pallor"followedby an "excitement—darkening" resulting from stimulationof beta adrenergic receptors which causes dispersion of melaningranules within localized populations of melanophores. Thus,in Anolis, dispersion of melanin granules within melanophoresis regulated by both MSH and by catecholamines. Evidence ispresented that the intracellular level of cyclic 3', 5'-AMPwithin melanophores may be responsible for the regulation ofmovement of melanin granules.     

Melanophore pigment dispersion responses to agonists show two patterns of sensitivity to inhibitors of cAMP-dependent protein kinase and protein kinase C

Melanophore pigment dispersion is a sensitive bioassay for activation of the adenylyl cyclase and phospholipase C second-messenger pathways. The necessity of protein kinase activation in causing pigment dispersion was confirmed for eight agonists of endogenous melanophore receptors and for two transfected receptors. All agonists and receptors previously shown to elevate intracellular cAMP in melanophores—melanocyte stimulating hormone, light, (−) norepinephrine, 5-hydroxytrptamine, and the β₂-adrenergic receptor—were able to stimulate pigment dispersion in the presence of Ro31-8220, a potent inhibitor of protein kinase C, but were blocked in the presence of H89, an inhibitor of cAMP-dependent protein kinase. The bombesin receptor, which elevates intracellular IP₃ in melanophores, was unable to stimulate pigment dispersion in the presence of Ro31-8220 or H89. Agonists whose mechanism of activation of pigment dispersion are unknown were also tested. Endothelin 3 responses were blocked by both H89 and Ro31-8220, predicting coupling to phospholipase C. Vasoactive intestinal polypeptide, oxytocin, and calcitonin gene-related peptide β responses were blocked only by H89, predicting coupling to adenylyl cyclase. © 1996 Wiley-Liss, Inc.     

Evidence for the presence of novel β-melatonin receptors along with classical α-melatonin receptors in the fish Rasbora daniconius (Ham.)

Abstract

The effects of melatonin (MT) were examined on the isolated scale melanophores from dorso-lateral (D-L) and band regions of a tropical fish Rasbora daniconius. Our study primarily aimed for further depiction of the signaling receptors involved in MT mediated pigment translocations in the fish. Melanophore Size Index (MSI) was employed as a recording parameter for the responses of melanophores to MT and various antagonists. MT has induced aggregation as well as dispersion in D-L region and aggregation in band region melanophores during summer season. During winter, MT-induced responses were only of aggregatory type in D-L region, while in the band region there was an increase in the sensitivity. The responses of the melanophores to MT were reversible. The aggregation of innervated melanophores induced by MT on the D-L and band regions was partially mediated through the neurotransmitters released under the influence of MT and partially by the specific MT receptors. Luzindole and K185 have completely blocked the aggregatory responses of D-L and band region melanophores. Aggregatory receptors may be of the conventional α-MT type. Dispersion of D-L and band region melanophores induced by MT in the presence of various antagonists and on denervated band region could be the result of activation of β-MT receptors of dispersive nature. Presence of α and β MT receptors is thus indicated in this fish melanophores.     

The stimulatory effects of prostaglandins on the melanophores of the lizard, Anolis carolinensis

The melanosome dispersing activity of prostaglandins PGE1, PGE2, PGF1 alpha, PGF2 alpha, PGI2 and 6 beta PGI, was tested on the melanophores of Anolis carolinensis. Only PGE2 and PGE1 were active and while PGE2 was the most potent and acted synergistically with alpha-MSH, PGE1 was additive with alpha-MSH. Arachidonic acid also stimulated melanosome dispersion but its effect was blocked by indomethacin suggesting an action through its conversion to PGE1 or PGE2. The effect of alpha-MSH, on the other hand, was unaltered by indomethacin which suggests that alpha-MSH stimulated melanosome dispersion does not depend upon prostaglandin synthesis. Thus, while some prostaglandins may interact with alpha-MSH to stimulate melanosome dispersion they are unlikely to mediate its action.     

Spectral sensitivity of melanophores of a freshwater teleost, Zacco temmincki

1. The melanophores of a freshwater teleost, Zacco temmincki, responded to changes in illumination: in darkness the melanophores induced a melanosome aggregation and when subjected to light they caused a melanosome dispersion. 2. Using monochromatic light, the spectral sensitivity of the melanophores was examined. 3. The melanophores showed a different sensitivity to light between 400 and 600 nm with a maximum at about 525 nm. 4. The action spectrum closely resembled a porphyropsin absorbance curve, suggesting a porphyropsin or similar photopigment is active in the melanophore light response of Zacco temmincki.     

Pigment movements in fish melanophores: Morphological and physiological studies

Summary Cyclic adenosine monophosphate (cAMP) has been shown to cause pigment dispersion in amphibian and fish melanophores. Since pigment displacements in melanophores of Pterophyllum scalare are known to be accompanied by assembly and disassembly of microtubules, the effect of cAMP on this process was investigated. Melanophores of isolated scales were treated with cAMP in the presence of vinblastine, a potent antimicrotubular agent. During the initial phase of vinblastine action, cAMP as well as its dibutyryl derivative are capable of counteracting the inhibitory effects of vinblastine on pigment dispersion. In addition, cAMP retains the velocity of pigment dispersion at about the maximum level during 1 hour experiments. Pigment aggregation was unaffected by cAMP. Since pigment dispersion in Pterophyllum-melanophores is accompanied by assembly of microtubules, it is concluded that cAMP influences, at least in part, melanosome dispersion through facilitation of microtubule assembly.     

Maxadilan Activates PAC1 Receptors Expressed in Xenopus laevis Melanophores

Functional interactions between ligands and their cognate receptors can be investigated using the ability of melanophores from Xenopus laevis to disperse or aggregate their pigment granules in response to alterations in the intracellular levels of second messengers. We have examined the response of long‐term lines of cultured melanophores from X. laevis to pituitary adenylate cyclase activating peptide (PACAP), a neuropeptide with vasodilatory activity, and maxadilan, a vasodilatory peptide present in the salivary gland extracts of the blood feeding sand fly. Pituitary adenylate cyclase activating peptide increased the intracellular levels of cyclic adenosine monophosphate (cAMP) and induced pigment dispersion in the pigment cells, confirming that melanophores express an endogenous PACAP receptor. Maxadilan did not induce a response in non‐transfected melanophores. When the melanophores were transfected with complementary DNA (cDNA) from the three different members of the PACAP receptor family, maxadilan induced pigment dispersion specifically and cAMP accumulation in melanophores transfected with the cDNA for PAC1 receptors but not VPAC1 or VPAC2 receptors. A melanophore line was generated that stably expresses the PAC1 receptor.